A hydraulic crane comprising: —a rotatable column (7); —a crane boom system (10) comprising two or more liftable and lowerable crane booms (11, 13); and—an electronic control device (25), which is configured to prevent an execution of crane boom movements that would make the lifting moment of the crane exceed the maximum allowed lifting moment of the crane, and to continuously establish position information as to the prevailing position of the load suspension point (P) of the crane boom system. When the lifting moment of the crane has reached a limit value at a given level below the maximum allowed lifting moment, the electronic control device is configured to prevent the execution of any combination of crane boom movements that would increase the horizontal distance between the load suspension point and said vertical axis of rotation and at the same time allow the execution of any combination of crane boom movements that keeps said horizontal distance unchanged or reduces said horizontal distance.

A hydraulic crane comprising: —a rotatable column (7); —a crane boom system (10) comprising two or more liftable and lowerable crane booms (11, 13); and—an electronic control device (25), which is configured to prevent an execution of crane boom movements that would make the lifting moment of the crane exceed the maximum allowed lifting moment of the crane, and to continuously establish position information as to the prevailing position of the load suspension point (P) of the crane boom system. When the lifting moment of the crane has reached a limit value at a given level below the maximum allowed lifting moment, the electronic control device is configured to prevent the execution of any combination of crane boom movements that would increase the horizontal distance between the load suspension point and said vertical axis of rotation and at the same time allow the execution of any combination of crane boom movements that keeps said horizontal distance unchanged or reduces said horizontal distance.

A vibration control system for a radio controlled device, including a radio controller and a radio receiver. The radio controller is configured to provide control commands to the radio receiver, including activation and deactivation of vibration control. One of the radio receiver or the radio controller includes a vibration control configured to provide vibration control commands to the radio controlled device.

An aerial work vehicle (AWV) includes a boom, and a work platform coupled to a distal end of the boom, where the work platform has a forward end in a direction of travel and an aft end opposite the forward end. The AWV also includes a first control device mechanically coupled to one of the forward end of the work platform or the aft end of the work platform and configured to control operation of at least the boom. In addition, the AWV includes an alternate, second, control device configured to control operation of at least the boom, which may be at least one of wireless and/or mechanically coupled to the work platform at a location different from a location of the first control device.

A crane comprising a traveling body and a turning body turnably supported by the traveling body, the crane performing power feeding and communication between the traveling body and the turning body. The traveling body is provided with: a power supply; a lower controller which controls the traveling body and transmits power to the devices included in the traveling body; and a lower transmitter-receiver which wirelessly transmits and receives the power and data signal from the power supply. The turning body is provided with: an upper controller which controls the turning body and transmits power to the devices included in the turning body; and an upper transmitter-receiver which wirelessly transmits and receives the power and data signal to and from the lower transmitter-receiver.

A crane comprising a traveling body and a turning body turnably supported by the traveling body, the crane performing power feeding and communication between the traveling body and the turning body. The traveling body is provided with: a power supply; a lower controller which controls the traveling body and transmits power to the devices included in the traveling body; and a lower transmitter-receiver which wirelessly transmits and receives the power and data signal from the power supply. The turning body is provided with: an upper controller which controls the turning body and transmits power to the devices included in the turning body; and an upper transmitter-receiver which wirelessly transmits and receives the power and data signal to and from the lower transmitter-receiver.

A load-handling crane, and a system and method are provided for operating the load-handling crane having a hoist movable by means of a drive of the crane and a handling device for operating the crane. The handling device is fastened to a liftable and lowerable suspension element of the hoist and having a sensor system for determining an orientation of the suspension element, or of a part fastened to the suspension element, or of the handling device, or of a load-handling attachment. The system further has an operating element that cooperates with the sensor system such that, when the operating element is actuated, a control command for activating the drive is able to be triggered, resulting in the hoist being movable by means of the drive in a direction of travel, with the direction of travel being dependent on an orientation determined by means of the sensor system.

A load-handling crane, and a system and method are provided for operating the load-handling crane having a hoist movable by means of a drive of the crane and a handling device for operating the crane. The handling device is fastened to a liftable and lowerable suspension element of the hoist and having a sensor system for determining an orientation of the suspension element, or of a part fastened to the suspension element, or of the handling device, or of a load-handling attachment. The system further has an operating element that cooperates with the sensor system such that, when the operating element is actuated, a control command for activating the drive is able to be triggered, resulting in the hoist being movable by means of the drive in a direction of travel, with the direction of travel being dependent on an orientation determined by means of the sensor system.

The invention relates to a system for central control of one or more cranes including at least one crane and at least one central control station, wherein the crane includes one or multiple image sensors observing a picked-up load, at least part of the crane surroundings and at least part of the crane structure, the crane is connected with the control station for the transmission of the image sensor data via at least one bidirectional communication link, and wherein the control station comprises at least one display element for the visual representation of the received sensor data as well as provides at least one input device for inputting control commands, and the control commands can be transmitted, via the communication link, to one or more crane actuators and/or the crane control for performing crane movements.

The invention relates to a system for central control of one or more cranes including at least one crane and at least one central control station, wherein the crane includes one or multiple image sensors observing a picked-up load, at least part of the crane surroundings and at least part of the crane structure, the crane is connected with the control station for the transmission of the image sensor data via at least one bidirectional communication link, and wherein the control station comprises at least one display element for the visual representation of the received sensor data as well as provides at least one input device for inputting control commands, and the control commands can be transmitted, via the communication link, to one or more crane actuators and/or the crane control for performing crane movements.